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基于旋转矩阵描述的航天器无角速度测量姿态跟踪无源控制 被引量:11

Rotation matrix based passive attitude tracking control of spacecraft without angular velocity measurements
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摘要 利用系统无源性和旋转矩阵性质研究无角速度测量下的姿态跟踪控制问题.为了避免姿态参数的奇异性和模糊性,提出基于三维特殊正交群(SO(3))的控制策略.首先利用旋转矩阵建立姿态跟踪误差方程,然后分析了系统的内在无源性,从而揭示了闭环系统的稳定性.当角速度无法获得时,利用新的无源滤波提出一种无角速度测量控制律,并给出了严格的Lyapunov稳定性分析.最后,通过数值仿真验证了所提出的控制方法的有效性. Attitude tracking control without angular velocity measurements is investigated by using the passivity of the system and the property of rotation matrix. The control scheme developed on the special orthogonal group(SO(3)) is proposed to avoid ambiguities and singularities of attitude parameters. Firstly, the equations of attitude tracking error are established by using the rotation matrix. Then, the inherent passivity of the system is analyzed to reveal the stability of the closed-loop system. With the use of a novel passive filter, a controller without angular velocity is proposed while the velocity measurements may not be available. The strict Lyapunov stability analysis is also presented. Finally, numerical simulations validate the effectiveness of the proposed control method.
作者 郑重 宋申民
机构地区 哈尔滨工业大学控制理论与制导技术研究中心
出处 《控制与决策》 EI CSCD 北大核心 2014年第9期1628-1632,共5页 Control and Decision
基金 国家自然科学基金项目(61174037) 国家973计划项目(2012CB821205) CAST创新基金项目(CAST20120602)
关键词 姿态跟踪 旋转矩阵 无源控制 无速度反馈 Barbalat引理 attitude tracking rotation matrix passivity-based control velocity-free feedback Barbalat’s lemma
分类号 V448.2 [航空宇航科学与技术—飞行器设计]
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参考文献18

  • 1Wen J T, Kreuta-Delgado K. The attitude control problem[J]. IEEE Trans on Automatic Control, 1991, 36(10): 1148-1162.
  • 2Du H B, Li S H. Finite-time attitude stabilization for a spacecraft using homogeneous method[J]. J of Guidance Control and Dynamics, 2012, 35(3): 740-748.
  • 3程小军,崔祜涛,徐瑞,崔平远.几何约束下的航天器姿态机动控制[J].控制与决策,2012,27(5):724-730. 被引量:7
  • 4Bhat S, Bernstein D. A topological obstruction to continuous global stabilization of rotational motion and the unwinding phenomenon[J]. Systems and Control Letters, 2000, 39(1): 63-70.
  • 5Chaturvedi N, Sanyal A, Mcclamroch N. Rigid-body attitude control[J]. IEEE Control System Magazine, 2011, 31(3): 30-51.
  • 6Fragopoulos D, Innocenti M. Stability considerations in quaternion attitude control using discontinuous Lyapunov functions[J]. IEE Proc of Control Theory and Applications, 2004, 151(3): 253-258.
  • 7Mayhew C G, Sanfelice R G, Teel A R. Quaternion-based hybrid control for robust global attitude tracking[J]. IEEE Trans on Automatic Control, 2011, 56(11): 2555-2566.
  • 8Mayhew C G, Sanfelice R G, Sheng J S, et al. Quaternion-based hybrid feedback for robust global attitude synchronization[J]. IEEE Trans on Automatic Control, 2012, 57(8): 2122-2127.
  • 9Schlanbusch R, Loria A, Nicklasson P J. On the stability and stabilization of quaternion equilibria of rigid bodies[J]. Automatica, 2012, 48(12): 3135-3141.
  • 10Sanyal A K, Fosbury A, Chaturvedi N A, et al. Inertia-free spacecraft attitude trajectory tracking with disturbance rejection and almost global stabilization[J]. J of Guidance Control and Dynamics, 2009, 32(4): 1167-1178.

二级参考文献15

  • 1Mengali G, Quarta A A. Spacecraft control with constrained fast reorientation and accurate pointing[J]. The Aeronautical J, 2004, 108(1080): 85-91.
  • 2Mclnnes C R. Large-angle slew maneuvers with autonomous sun vector avoidance[J]. J of Guidance Control and Dynamics, 1994, 17(4): 875-877.
  • 3Avanzini G, Radice G, Ali I. Potential approach for constrained autonomous manoeuvres of a spacecraft equipped with a cluster of control moment gyroscopes[J]. J of Aerospace Engineering, 2009, 223(3): 285-296.
  • 4Wisniewski R, Kulczycki P. Slew maneuver control for spacecraft equipped with star camera and reaction wheels[J]. Control Engineering Practice, 2005, 13(3): 349- 356.
  • 5Frazzoli E, Dahleh M A, Feron E, et al. A randomized attitude slew planning algorithm for autonomous spacecraft in AIAA guidance[C]. Navigation, and Control Conf and Exhibit. Montreal: AIAA, 2001: 1-8.
  • 6Kim Y, Mesbahi M. Quadratically constrained attitude control via semidefinite programming[J]. IEEE Trans on Automatic Control, 2004, 49(5): 731-735.
  • 7Kim Y, Mesbahi M, Singh G, et al. On the convex parameterization of constrained spacecraft reorientation[J]. IEEE Trans on Aerospace and Electronic Systems, 2010, 46(3): 1097-1109.
  • 8Huntington G T, Rao A V. Optimal reconfiguration of spacecraft formations using the Gauss pseudospectralmethod[J]. J of Guidance Control and Dynamics, 2008, 31(3): 689-698.
  • 9Ross I M, Gong Q, Sekhavat P. Low-thrust, high-accuracy trajectory optimization[J]. J of Guidance Control and Dynamics, 2007, 30(4): 921-933.
  • 10Fleming A, Sekhavat P, Ross I M. Minimum-time reorientation of a rigid body[J]. J of Guidance Control and Dynamics, 2010, 33(1): 160-170.

共引文献6

同被引文献92

  • 1崔平远,秦同,朱圣英.火星动力下降自主导航与制导技术研究进展[J].宇航学报,2020,41(1):1-9. 被引量:18
  • 2赵羲,马东洋,刘毅锟,蓝朝桢.基于GPU的小行星实时成像模拟[J].系统仿真学报,2009,21(S1):110-112. 被引量:2
  • 3韩京清.一类不确定对象的扩张状态观测器[J].控制与决策,1995,10(1):85-88. 被引量:422
  • 4孙丽,秦永元.捷联惯导系统姿态算法比较[J].中国惯性技术学报,2006,14(3):6-10. 被引量:48
  • 5Bouabdallah S. Design and control of quadrotors withapplication to autonomous flying[J]. Ecole PolytechniqueFederale de Lausanne, 2007,3727: 61.
  • 6Bouabdallah S, Siegwart R. Backstepping andsliding-mode techniques applied to an indoor microquadrotor[C]. Int Conf on Robotics and Automation.Barcelona: IEEE, 2005: 2247-2252.
  • 7Bristeau P-J,Callou F, Vissire D. The navigation andcontrol technology inside the ar. drone micro uav[C]. The18th IFAC World Congress. Milano, 2011: 1477-1484.
  • 8Lim H, Park J, Lee D. Build your own quadrotor: Open-source projects on unmanned aerial vehicles[J]. Robotics&Automation Magazine, 2012,19(3): 33-45.
  • 9Zhou Q L,Zhang Y, Rabbath C. Design of feedbacklinearization control and reconfigurable control allocationwith application to a quadrotor UAV[C]. 2010 Conf onControl and Fault-Tolerant Systems. Nice: IEEE, 2010:371-376.
  • 10Lee D, Kim H J, Sastry S. Feedback linearization vs.adaptive sliding mode control for a quadrotor helicopter[J].Int J of Control, Automation and Systems, 2009,7(3): 419-428.

引证文献11

二级引证文献72

控制与决策
2014年 第9期

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